WO2015011372A1 - Valve, notably for combustion engine - Google Patents

Abstract

The invention relates to a valve (1), notably for a combustion engine, comprising: - a body (7) in which are formed: a duct (3) through which a fluid can pass and two housings (8) accommodating a bearing and the bearing being some distance from the duct (3), and - a shutter (5) pivot-mounted in the body (7) via the two bearings, the shutter (5) comprising: - a first part (10) having a first surface one portion of which defines a first zone of contact with the body (7) when the shutter is in the closed position, - a second part (12) having a second surface of which a portion defines a second zone of contact with the body (7) when the shutter (5) is in the closed position, the first zone and the second zone belonging to opposite surfaces of the shutter (5) and being coplanar on a plane intersecting the bearings, the shutter (5) being configured in such a way that a clearance (14) is formed at least in a portion of said shutter (5) which portion is located between a bearing and the duct (3), so as to allow the shutter (5) to pivot without contacting the body (7).

Description

 VA E, IN PARTICULAR FOR THERMAL MOTORS

The invention relates to a valve, in particular for a heat engine. The invention applies in particular when the heat engine is used for the propulsion of a vehicle, for example a motor vehicle. It can be an engine whose fuel is gasoline or diesel. The valve can be integrated in the air circuit of the engine.

 For the purposes of the invention, the term "thermal engine air circuit" means the recirculation between the inlet ad m ission and the exhaust outlet of the engine. The valve can be arranged in the intake circuit, the exhaust circuit, or a recirculation loop through which the exhaust gases fed back to the inlet (EGR in English) pass. The valve can thus be traversed by exhaust gases at high temperature.

 In the case of a valve comprising:

 a body in which is formed a conduit in which a fluid passes, and

 a flap mounted movably in the body between an open position and a closed position in which it must close the duct coming into contact with a gasket mounted in the duct, leakage problems of the valve when the shutter is in the closed position; especially due to the operating temperatures of the valve.

 There is a need to benefit from a valve overcoming the above drawbacks.

 According to one of its aspects, the invention responds to this need with the aid of a valve, particularly for a heat engine, comprising:

 a body in which are provided: a duct adapted to be traversed by a fluid and two housings, each housing receiving a landing and being at a distance from the duct, and

 a flap pivotally mounted in the body via the two palms, the door comprising:

 a first part having a first surface, a portion of which defines a first zone of contact with the body when the shutter is in the closed position,

a second part having a second surface, a portion of which defines a second zone of contact with the body when the shutter is in closed position,

the first zone and the second zone belonging to opposite surfaces of the shutter and being coplanar in a plane intersecting the bearings,

the flap being configured so that a clearance is provided at least in a portion of said flap disposed between a bearing and the duct, so as to allow the pivoting of the flap without contacting the body.

 Each zone of contact of the shutter with the body when the shutter is in the closed position can correspond to a plane-to-plane contact according to a single sealing plane. With such a valve, the shutter makes plane-to-plane contact with the body when in the closed position.

 The first part and the second part of the shutter can be assembled according to a joining plan of the shutter. This junction plane of the flap can be confused with the sealing plane.

 The body can be made, at least at the level of the shutter, in at least two elements in contact with each other according to a junction plane of the body. The surfaces of the body in contact with the shutter when the latter is in the closed position may belong to this plane joining the body.

 In other words, one and the same plane can be at a time:

 - the junction plane of the shutter,

 the sealing plane in which the plane-to-plane contact is engaged between the shutter and the body when the shutter is in the closed position, and

 - the plan of joining the body.

 The flap may comprise a shaft received in the bearings, at least one bearing being configured to allow a radial displacement of the shaft in the bearing when the flap is moved from the open position to the closed position.

 The valve may comprise at least one return member fixed to the body, the return member being configured to guide said radial displacement of the shaft in a predetermined direction.

 Alternatively, the valve may comprise at least one drive member configured to move the shaft so that the flap pivots between the open position and the closed position, the drive member being configured to guide said radial displacement. of the shaft in a predetermined direction.

The clearance in the bearing or bearings may prevent jamming of the flap against the duct wall when the flap passes into the closed position without the need to meet dimensional constraints too demanding between the flap and the part of the duct in which it moves while avoiding the increase of the leakage sections when the shutter is in the closed position.

 The return member or the drive member guiding the radial displacement of the shaft in a predetermined direction makes it possible to ensure that the additional clearance in the bearings is used to prevent the increase of the leakage sections between the shutter and body when the shutter is in the closed position.

 The shutter and the body can be configured so that the axis of rotation of the flap is part of the sealing plane.

 The axis of rotation of the flap can belong to the plane cutting the bearings. Thus the flap may have an axis of rotation forming the axis of symmetry of the flap surface located inside the duct. As a result, when the flap is in the open position, the pressure exerted by the fluid on the flap is substantially the same on either side of the axis.

 The first and second contact areas may be adjacent. Thus, when the flap is in the closed position, the first and second contact zones meet. Leaks when the flap is in the closed position are thus reduced, being limited to the tolerances on the dimensions of the various parts making up the valve.

 At least one cavity may be formed in the body and disposed between a bearing and the conduit, for receiving the portion of the flap extending between said bearing and the conduit.

 The flap may delimit, when in the closed position, two distinct fractions of the duct and the cavity may be connected to the duct so that it communicates directly with only one of said duct fractions when the shutter is in position closed. Considering the flow direction of the fluid in the valve, the flap can then delimit a first fraction of the duct upstream of the flap and a second fraction of the duct downstream of the flap.

 Thus, when the flap is in the closed position, the first fraction is in contact with the fluid and the second fraction is not in contact with the fluid.

 A fraction of the duct communicating via the leaks existing when the shutter is in the closed position with the other fraction of the duct, this other fraction being directly in contact with the cavity, is not itself directly in contact with the cavity in the of this application.

According to a first embodiment, the shaft is received in the bearings and extends continuously between these bearings, the shaft carrying the first and second part of the shutter. According to this first embodiment, the shaft is distinct from the first and second part of the flap.

 The shaft may comprise two curved portions each forming the clearance for pivoting the shutter without contacting the body, each of said portions being disposed between a bearing and the conduit.

 The curved portions may be such that outside of these curved portions, the shaft contacts the sealing plane when the flap is in the closed position.

 The shaft can be rigidly coupled to the first and second parts of the flap at the level of the zone along which it contacts the sealing plane.

 Thus, the first and second parts of the flap are rigidly fixed to the shaft over the entire length between the curved portions.

 In a variant, the curved portions may be such that, outside these curved portions, the shaft contacts the sealing plane in at least one zone whose length, measured along the shaft, is less than length separating the curved portions. The shaft can thus provide one or more areas in which it contacts the sealing plane, these areas being located between the curved portions. The shaft is thus rigidly coupled to the first and second parts of the flap by at least one attachment zone.

 Each clearance can be formed by two successive bends, formed on the shaft, the shaft thus forming at each clearance substantially a "U". Such clearance allows to have a tree formed in one piece.

 According to a second embodiment, the shaft may comprise distinct portions that are distinct from the first and second parts of the shutter. The shaft comprises for example two clean portions, each clean portion being received in a bearing and extending between the bearing and the corresponding clearance, each clean portion being connected to one of the first and second parts of the flap, so that the shaft can extend continuously between the bearings by combining the clean portions and at least a portion of the first or second portion of the flap.

Unlike the first embodiment, in which the shaft extends between the bearings by means of a separate part of the first and second part of the flap and dedicated to the shaft function, the shaft according to the second Embodiment may be formed at the duct by at least a portion of one of the first and second portions of the flap. Thus, at least a portion of a portion of the flap can be used both to close the duct when the flap is in the closed position, to support the flap in the duct, and to transmit to the flap a movement for pivoting.

 This reduces the clutter induced by the flap when the latter is in the open position.

 The first part of the component can thus define the tree between the two clean portions of the latter.

 Alternatively, the second part of the flap can define the shaft between the two clean portions of the latter.

 Each clean portion of the shaft may comprise a flat part through which the connection is made to the first or second part of the flap.

 This connection can make it possible to ensure continuity of the shaft at the level of the conduit.

 The first or second part of the flap may comprise two clearances each extending only on one side of the axis of rotation of the flap so as to allow the flap to pivot, said two clearances being then separated by at least the portion of said first or second portion of the flap extending into the conduit.

 The first or second part of the flap can extend on either side of the axis of rotation of the flap, in a part of the cavity. The first or second part of the flap may extend on either side of the axis of rotation of the flap, at least in part of the duct.

 The first or second part of the flap may comprise at least one wide zone and at least two narrow zones, the narrow zones being situated at least at the level of the recesses and the wide zone being located at least at the level of the duct.

 Each clearance may extend between the duct and the landing.

 The first or second part of the flap may comprise two connecting portions cooperating with the corresponding eigenvector portion of the shaft via the flat, each po ertion of the iso n eta nt d isposed between the pa lier and the corresponding release .

 Each connecting portion may be rigidly coupled with the proper portion of the corresponding shaft via the flat part of the latter.

Each connecting portion may extend on either side of the axis of shutter rotation.

 Alternatively, each connecting portion may extend only one side of the axis of rotation of the flap.

 Each clearance may comprise a first bevel facing a second bevel formed in the body, so as to allow the pivoting of the flap without contacting the body.

 The first bevel can form an acute angle with the plane defined by the first and second contact areas of the flap, for example less than strictly 90 °, especially less than 45 °.

 The second bevel can form an acute angle with the sealing plane, for example less than strictly 90 °, especially less than 45 °.

 The valve can be arranged in the intake circuit, the exhaust circuit, or a recirculation loop through which the exhaust gases fed back to the inlet (EGR in English) pass. The valve can thus be traversed by exhaust gases at high temperature.

 Advantageously, the valve can be placed in a high pressure recirculation loop. A "high-pressure recirculation loop" is a loop that recovers exhaust gases upstream of the turbine and reinjects them downstream of the compressor.

 In another variant, the valve may be placed in a low pressure recirculation loop. A "low pressure recirculation loop" is called a loop that recovers exhaust gases downstream of the turbine and reinjects them upstream of the compressor.

 The invention will be better understood on reading the following description of a nonlimiting example of implementation thereof and on examining the appended drawing in which:

 - Figures 1 to 5 relate to a valve according to the invention, the valve being shown in the closed position, Figure 1 showing in perspective the valve, Figure 2 showing in perspective the valve of Figure 1, a part of the body having been removed to reveal certain elements thereof, FIG. 3 showing in a view from above the valve of FIGS. 1 and 2, FIG. 4 showing in section along AA, BB, CC, DD and EE the valve of FIGS. at 3, FIG. 5 representing a detail shown at F on the section along CC of FIG. 4,

FIGS. 6 to 9 can be seen in FIG. 1 to 5, respectively according to the representation of Figures 1 to 4, the valve being in position in which it began its pivoting to open the conduit, and

 FIGS. 10 to 14 relate to the valve of FIGS. 1 to 9, respectively according to the representation of FIGS. 1 to 5, the valve being substantially in the maximum open position of the conduit, FIG. 14 representing a detail represented at F on the cut along CC of Figure 13.

 FIGS. 1 to 3 show a valve 1 for an internal combustion engine. This valve 1 is for example intended to be mounted in a recirculation loop of the high pressure exhaust gas. Under these conditions, the temperature of the gases can reach 700 ° C.

 This valve 1 comprises:

 a body 7 in which are provided: a conduit 3 adapted to be traversed by a fluid and two housings 8, each housing receiving a bearing 4 and being at a distance from the conduit 3, and

a flap 5 pivotally mounted in the body 7 via the two bearings 4.

 The flap 5 is here received with a clearance allowing it to move radially in each of the bearings 4.

 The body 7 comprises in this example two elements 2 and 6 at the flap 5. These two elements 2 and 6 are assembled in a plane called "body junction plane".

 Stream 5 includes:

 a first portion 10 having a first surface 11, a portion of which defines a first zone of contact with the element 6 of the body 7 when the flap is in the closed position,

a second part 12 having a second surface 13, a portion of which defines a second zone of contact with the element 2 of the body 7 when the flap is in the closed position.

In the example shown, the first 10 and second 12 parts of the flap 5 are formed by two sheets and are obtained by cutting and stamping. These two parts are laser welded together or are assembled together by screwing, crimping or riveting. The assembly between the first 10 and the second part 12 of the flap 5 can be carried out according to a junction plane of the flap. Two flat surfaces respectively belonging to the first 10 and the second portion 12 of the flap 5 are then secured against each other. Each of the first 10 and the second portion 12 is in the example in the form of a plate, that is to say a parallelepiped of low height. The welding between the two parts 10 and 12 is effected via two facing faces.

 In the example under consideration, the duct 3 has, at the level of the bearings 4, a substantially circular cross section and each of the first 10 and the second 12 of the door 5 has a substantially circular profile. . The first zone and the second zone belong to opposite surfaces of the shutter 5 and are coplanar in a plane intersecting the bearings 4. The axis of rotation 20 of the shutter 5 belongs to this plane intersecting the bearings.

 The first part 10 of the flap 5 extends on either side of the axis of rotation.

 The second portion 12 of the flap 5 extends on either side of the axis of rotation, in a portion of the duct 3.

 The second portion 12 of the flap 5 comprises two clearances 14, each clearance 14 being formed in the flap between a bearing 4 and the duct 3, so as to allow the pivoting of the flap without contacting the element 6 of the body 7.

 Two cavities 15 are formed in the element 6 of the body 7. Each cavity 15 is disposed between a bearing 4 and the duct 3 and makes it possible to receive the portion of the flap extending between the bearing 4 and the duct 3.

 In the example shown, these cavities are obtained directly by press-molding of the part forming the element 6 of the body 7.

 When in the closed position, the flap 5 defines two distinct fractions of the duct 3. Each fraction is located on either side of the flap 5. The two cavities 15 extend in the example considered on the same side relative to to the contact plane defined by the contact between the flap 5 and the body7 when the flap is in the closed position. The two cavities 15 are thus connected to the duct 3 so that they only communicate directly with a single fraction of the duct when the flap is in the closed position.

 The flap 5 comprises a shaft 21 comprising two clean portions 22, 23.

Each clean portion 22, 23 is received in a bearing 4 and extends between the bearing 4 and the clearance 14 corresponding. This shaft is adapted to be rotated in the conduit 3 by an actuator not shown in the figures.

Each clean portion 22, 23 is connected to the second portion of the flap 5, so that the shaft 21 can extend continuously between the bearings 4 by the combination of the clean portions 22, 23 and the second portion of the flap 5.

Each clean portion 22, 23 of the shaft 21 comprises a flat part through which the connection is made to the second part of the flap.

 The axis of rotation 20 of the flap 5 belongs in this example to the plane defined by each flat.

 The connection is made by laser welding, screwing, crimping or riveting. This connection is made via two connecting portions 24, 25 formed on the second part 12 of the flap 5. These connecting portions 24, 25 are arranged between the bearing 4 and the corresponding clearance 14. These connecting portions 24, 25 extend on either side of the axis of rotation of the flap 5.

 The two clearances 14 of the example considered each extend only on one side of the axis of rotation 20 of the flap 5 and are separated by the portion of the first part of the flap which extends in the duct. 3. Each clearance 14 comprises a first bevel 26, 27 facing a second bevel 28, 29 formed in the element 6 of the body 7. Each first bevel 26, 27 is longer than the second bevel 28, 29 coming from next to the first, the length being measured along the axis of rotation 20 of the flap.

 FIG. 4 shows the sectional views along AA, BB, CC, DD and EE of the valve of FIGS. 1 to 3, the cutting lines being represented in FIG. 3. In the example represented, the body has two coplanar surfaces on which the flap 5 comes into contact with its first 10 and second 12 parts, when it is in the closed position. A first surface belonging to the element 6 of the body 7 comes into planar contact with a first contact zone with the first surface 11 of the first part 10 of the shutter when it is in the closed position and a second surface belonging to the element 2 of the body 7 comes into contact pl an on pl an according to a second contact zone with the second surface 13 of the second portion 12 of the flap 5. These contact zones are in this example coplanar, belonging to a single sealing plane.

 In the example, the junction plane of the body, the junction plane of the flap and the sealing plane between the flap 5 and the body 7 when the flap is in the closed position form a single plane.

The cuts along AA and BB represent the flap 5 and the body7 at the level of the duct 3. The cuts along CC to DD represent the flap 5 and the body 7 at one of the cavities 15 and more particularly at one of the clearances 14 of the second portion 12 of the flap 5.

 The cut along EE represents the flap 5 and the body 7, at one of the cavities 15 and more particularly the connecting portion 25 of the flap 5, the own portion 23 of the shaft 21 and the body 6, at the level of of the connecting portion 25.

 There is shown in Figure 5, a detail of the first and second bevels.

The first bevel 27 forms an angle of 45 °, with the surface 13 of the second portion 12 of the flap 5. The second bevel 29 forms an angle of 35 ° with the surface of the body 7 coming into contact with the first part 10 of the flap 5, when the flap 5 is in the closed position.

 The invention is not limited to the example which has just been described. In a variant not shown, the duct 3 has at the level of the bearings 4 a rectangular section and each of the first 10 and second portion 12 of the flap 5 has at the level of the duct 3 a substantially rectangular contour.

 The content of the application filed in France on October 10, 2012 by the Applicant under the number 1259688 is incorporated in the present application by reference, in particular in that it teaches how to size the game in the bearings to prevent jamming of the flap during its pivoting and how to obtain a single sealing plane which coincides with the junction plane of the body and the junction plane of the flap.

 The content of the application filed in France on June 20, 2013 by the Applicant under the number 13 55818 is incorporated herein by reference, in particular in that it teaches how to configure the return member to guide said radial displacement of the tree in a predetermined direction.

 The content of the application filed in France on June 20, 2013 by the Applicant under the number 13 55820 is incorporated in the present application by reference, even though it is intended as a co nf re r the drive member for guiding said radial displacement of the shaft in a predetermined direction.

 The expression "comprising a" shall be understood as synonymous with the expression "including at least one" unless the contrary is specified.

Claims

 Valve (1), in particular for a heat engine, comprising:

 - A body (7) da ns leq uel are provided: a cond u it (3) capable of being traversed by a fluid and two housings (8), each housing (8) receiving a bearing (4) and being away from the leads (3), and

 - a flap (5) pivotally mounted in the body (7) via the two bearings (4) the flap (5) comprising:

 a first portion (10) having a first surface (11), a portion of which defines a first zone of contact with the body (7) when the flap is in the closed position,

 a second portion (12) having a second surface (13), a portion of which defines a second zone of contact with the body (7) when the flap (5) is in the closed position,

the first zone and the second zone belonging to opposite surfaces of the shutter (5) and being coplanar in a plane intersecting the bearings (4), the shutter (5) being configured so that a clearance (14) is provided at least in a portion of said flap (5) disposed between a bearing (4) and the duct (3), so as to allow pivoting of the flap (5) without contacting the body (7).

 Valve (1) according to Claim 1, the part of the body (7) in contact with the first and the second contact zone, when the flap (5) is in the closed position, defining a sealing plane, and the flap ( 5) and the body (7) being configured so that the rotati on axis (20) of the flap (5) is part of said sealing plane.

 Valve according to Claim 2, the first part (10) and the second part (12) of the flap (5) being assembled in a junction plane of the flap, the body (7) being formed, at least at the level of the flap ( 5), in at least two elements (2, 6) in contact with each other along a junction plane of the body and the sealing plane, the junction plane of the body and the junction plane of the shutter belonging to in one and the same plane

Valve (1) according to any one of claims 1 to 3, at least one cavity (15) being arranged in the body (7) and arranged between a bearing (4) and the duct (3), to receive the portion of the flap (5) extending between said bearing (4) and the duct (3).

5. Valve (1) according to claim 4, the flap (5) defining, when in the closed position, two distinct fractions of the duct (3) and the cavity being connected to the duct (3) so that q u it communicates directly with only one of said fractions when the flap (5) is in the closed position.

 6. Va nne (1) sel lle une of previous revend icatio ns, the flap (5) comprising a shaft received in the bearings (4) and extending continuously between these bearings (4), the shaft carrying the first (10) and second (12) portion of the flap (5) and being distinct from the first (10) and second (12) portion of the flap.

 7. Valve (1) according to claim 6, the shaft comprising two curved portions each forming the clearance for pivoting the flap (5) without contacting the body (7), each of said portions being disposed between a bearing (4) and the conduit (3).

 8. Valve (1) according to one of claims 1 to 5, the flap (5) comprising a shaft (21) comprising two clean portions (22, 23), each clean portion being received in a bearing (4) and extending between the bearing (4) and the clearance (14) corresponding, each clean portion being connected to one of the first (10) and the second (12) part of the flap, so that the shaft (21) can extend continuously between the bearings (4) by the combination of the clean portions (22, 23) and at least a portion of the first (10) or second (12) portion of the flap (5) .

 9. Valve (1) according to claim 8, each clean portion (22, 23) of the shaft (21) comprising a flat by which is made the connection to the first (10) or the second (12) part of the shutter.

 10. Valve (1) according to claim 8 or 9, the first (10) or the second (12) part of the flap (5) comprising two clearances each extending only one side of the axis rotating (20) the flap (5) so as to allow pivoting of the flap (5), said two clearances (14) being then separated by at least the portion of said first (10) or second (12) part of the flap (5) extending into the conduit (3).

11. Valve (1) according to claims 9 and 10, the first (10) or the second (12) part of the flap (5) comprising two portions of the iaison (24, 25) cooperating with the clean portion (22, 23 ) corresponding to the shaft (21) via the flat, each connecting portion (24, 25) being disposed between the bearing (4) and the corresponding clearance (14).

 12. Valve (1) according to claim 11, each connecting portion (24, 25) extending on either side of the axis of rotation (20) of the flap.

 13. Van ne (1) according to the uuelconq ue resells 10 to 12, each clearance (14) comprising a first bevel (26, 27) facing a second bevel (28, 29) provided in the body (7), so as to allow the pivoting of the flap (5) without contacting the body (7).

 14. Valve (1) according to claim 13, the first bevel (26, 27) forming an acute angle with the plane defined by the first and second contact areas of the flap, for example less than strictly 90 °, especially less than 45 °.

 15. Valve (1) according to claim 14, the second bevel (28, 29) forming an acute angle with the sealing plane, for example strictly less than 90 °, especially less than 45 °.